Nucleic acid nanostructure barcode probes

ABSTRACT

Provided herein are, inter alia, barcode probes comprised of transiently or stably fluorescently labeled nucleic acid nanostructures that are fully addressable and able to be read using standard fluorescent microscope and methods of use thereof including methods of use as detectable labels for probes.

RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No. 13/882,223, filed Jun. 11, 2013, which is a national stage filing under 35 U.S.C. § 371 of International Application No. PCT/US2011/058458, filed Oct. 28, 2011, which was published under PCT Article 21(2) in English and claims the benefit of U.S. Provisional Application Ser. No. 61/408,358, filed on Oct. 29, 2010, the entire contents of each of which are incorporated by reference herein.

GOVERNMENT SUPPORT

This invention was made with U.S. Government support under grant numbers OD004641, HG005592 and OD007292 awarded by the National Institutes of Health, CCF-1054898 awarded by the National Science Foundation, and N00014-10-1-0827 and N00014-11-1-0914 awarded by the Office of Naval Research. The Government has certain rights in the invention.

REFERENCE TO A COMPACT DISK APPENDIX

A computer program listing is appended to this disclosure and is hereby incorporated herein by this reference. The appendix includes the file programlisting.txt which includes listings for 6ht-v5-1color-1.json and 6ht-v6-2color-1.json.

BACKGROUND OF INVENTION

A major challenge in modern biology and nanotechnology is to observe, identify and differentiate a large number of different molecular species in real time. Fluorescent microscopy is a powerful tool for non-destructively and dynamically monitoring many individual molecular events. However, the multiplexing ability of fluorescent imaging is limited by the number of spectrally non-overlapping fluorophores available. There is therefore a great need for novel addressable fluorescent probes useful in multiplex detection systems.

BRIEF SUMMARY OF INVENTION

The invention provides, inter alia, nucleic acid barcode probes that comprise a nucleic acid nanostructure comprising one or more fluorescently labeled regions that may be stably or transiently bound (and thus labeled) with fluorophore-bearing oligonucleotides. The barcode probes may further comprise a target binding moiety. The invention also provides methods of use for such barcode probes including but not limited to their use in analyte detection assays (e.g., assays for detecting and optionally quantitating one or more analytes). The nature of the fluorescent signals (e.g., the wavelength or “color”, intensity, etc.) and the pattern (or orientation, or arrangement or geometry) of such signals on the barcode can also be used to identify particular analytes in a sample. This facilitates multiplexed assays in which a plurality of analytes are detected simultaneously (or at a minimum with a single sample or a single aliquot from a sample).

In one aspect, the invention provides a method of detecting a target comprising: contacting a sample with a nucleic acid barcode probe, and determining whether the nucleic acid barcode probe binds to one or more components in the sample, wherein binding of the nucleic acid barcode probe to one or more components of the sample indicates presence of a target in the sample, and wherein the nucleic acid barcode probe comprises a nucleic acid nanostructure comprising a target binding moiety and at least two fluorescently labeled regions.

In some embodiments, the method further comprises identifying the target based on the color and/or orientation of the fluorescently labeled regions of the nucleic acid barcode probe bound to one or more components of the sample.

In some embodiments, whether the nucleic acid barcode probe binds to one or more components in the sample comprises contacting the nucleic acid barcode probe with soluble, transiently binding fluorophore-bearing oligonucleotides.

In some embodiments, the nucleic acid barcode probe comprises stably bound fluorophore-bearing oligonucleotides.

In another aspect, the invention provides a method of detecting a target comprising contacting the target with a nucleic acid barcode probe, under conditions sufficient for the target to bind to the nucleic acid barcode probe; separating the target from material that is not bound to the target; and detecting the presence of the nucleic acid barcode probe bound to the target, wherein the nucleic acid barcode probe comprises a nucleic acid nanostructure comprising a target binding moiety and at least two fluorescently labeled regions.

In some embodiments, the method further comprises identifying the target based on the color and/or orientation of the fluorescently labeled regions of the nucleic acid barcode probe bound to the target.

In some embodiments, detecting the presence of the nucleic acid barcode probe bound to the target comprises contacting the nucleic acid barcode probe with soluble, transiently bound fluorophore-bearing oligonucleotides.

In some embodiments, the nucleic acid barcode probe comprises stably bound fluorophore-bearing oligonucleotides.

In another aspect, the invention provides a nucleic acid barcode probe comprising a nucleic acid nanostructure, such as a DNA barcode probe comprising a DNA nanostructure, having at least two fluorescently-labeled regions. In some embodiments, the nanostructure comprises at least three fluorescently-labeled regions, and the orientation is determinable due to asymmetric spacing of the fluorescently-labeled regions. The locations of each of the fluorescently-labeled regions on the nanostructure are such that a pattern of the fluorescent labels is determinable based on the emission of visible light by the fluorescently-labeled regions. In some embodiments, the orientation of the barcode probe is determinable based on the emission of visible light by the fluorescently-labeled regions.

In some embodiments, each of the fluorescently-labeled regions has a center that is located at least 200 nm from the centers of the other fluorescently-labeled regions. In some embodiments, each of the fluorescently-labeled regions has a center that is located at least 250 nm from the centers of the other fluorescently-labeled regions. In some embodiments, each of the fluorescently-labeled regions has a center that is located at least about 25 nm, at least about 50 nm, or at least about 75 nm, or at least about 100 nm, or at least 150 nm from the centers of the other fluorescently-labeled regions.

In some embodiments, the nanostructure comprises a scaffold strand and plurality of staple strands. In some embodiments, the scaffold strand has a sequence derived from M13 bacteriophage. In some embodiments, the fluorescently-labeled regions of the DNA nanostructure comprise fluorophore-labeled staple strands. In some embodiments, the fluorophore-labeled staple strand is a transiently binding fluorophore-labeled staple strand. In some embodiments, the fluorophore-labeled staple strand is transiently binding at room temperature. In some embodiments, the fluorophore-labeled staple strand is 7-12 nucleotides in length. In some embodiments, the fluorophore-labeled staple strand is about 9 nucleotides in length. In some embodiments, the fluorophore-labeled staple strand is a stably binding fluorophore-labeled staple strand. In some embodiments, the fluorophore-labeled staple strand is a stably binding fluorophore-labeled staple strand at room temperature. In some embodiments, the fluorophore-labeled staple strand is at least 18 nucleotides in length, including in some embodiments 18-25 nucleotides in length.

In some embodiments, the fluorophore-labeled staple strands are directly labeled. In some embodiments, the fluorophore-labeled staple strands are indirectly labeled.

In some embodiments, the fluorophore-labeled staple strands have a staple domain hybridized to a scaffold strand and a handle domain hybridized to a fluorophore-labeled oligonucleotide. In some embodiments, the handle domain is 7-12 nucleotides in length. In some embodiments, the handle domain is about 9 nucleotides in length. In some embodiments, the handle domain is at least 18 nucleotides in length. In some embodiments, the handle domain is 18-25 nucleotides in length.

In some embodiments, the nanostructure is a nanotube. In some embodiments, the nanostructure is prepared using a DNA origami method. In some embodiments, the nanostructure comprises a single-stranded DNA tile. In some embodiments, the nanostructure comprises DNA hairpins.

In some embodiments, the barcode probe further comprises a target binding moiety. In some embodiments, the target binding moiety is a single-stranded nucleic acid complementary to a nucleic acid target. In some embodiments, the target binding moiety is an antibody. In some embodiments, the target binding moiety is a protein or peptide.

In some embodiments, wherein the nanostructure, once assembled, is sufficiently immutable in a resting state that the pattern of the fluorescent regions can be detected using light microscopy in that resting state. In some embodiments, the resting state comprises absence of an applied electric field.

In another aspect, the invention provides a composition comprising a plurality of any of the foregoing nucleic acid nanostructure barcode probes. In some embodiments, some or all members of the plurality are different from other members in the plurality. The members may differ from each other based on the target binding moiety and the signal and orientation (arrangements) of the barcode. In some embodiments, the plurality is equal to or less than 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 25, 30, 40, 50, 100, 200 or more. In some instances, the plurality is equal to or less than 216.

In another aspect, the invention provides a method of identifying a target nucleic acid comprising contacting the target nucleic acid with any of the foregoing barcode probes under conditions such that the target nucleic acid binds to the barcode probe; separating the target nucleic acid from material that is not bound to the target nucleic acid; and detecting the presence of the barcode probe bound to the target nucleic acid.

In another aspect, the invention provides a method of identifying a target protein or cell comprising contacting the target protein or cell with any of the foregoing barcode probes under conditions such that the target protein or cell binds to the barcode probe; separating the target protein or cell from material that is not bound to the target protein or cell; and detecting the presence of the barcode probe bound to the target protein or cell.

In another aspect, the invention provides a method of identifying a target protein or cell comprising contacting the target protein or cell with any of the foregoing barcode probes under conditions such that the target protein or cell binds to the barcode probe; separating the target protein or cell from material that is not bound to the target protein or cell; and detecting the presence of the barcode probe bound to the target protein or cell.

In another aspect, the invention provides a method of detecting a target comprising contacting a sample with any of the foregoing nucleic acid barcode probes, and determining whether the nucleic acid barcode probe binds to one or more components in the sample, wherein binding of the nucleic acid barcode probe to one or more components in the sample indicates presence of a target in the sample.

In some embodiments, the method further comprises removing components in the sample that are not bound to the nucleic acid barcode probe following the contacting step.

In some embodiments, the target is a nucleic acid, a protein, a peptide, or a cell, or a combination thereof.

In some embodiments, the presence of the barcode probe is detected by fluorescent microscopy.

In some embodiments, the presence of the barcode probe is detected without exposing the DNA barcode probe to an electric field.

In some embodiments, each probe comprises a nucleic acid nanostructure having at least two fluorescently-labeled regions and a target binding moiety, wherein the locations of each of the fluorescently-labeled regions on the nanostructure are such that a pattern of the fluorescent labels of the barcode probe and the identity of the target binding moiety is determinable based on the emission of visible light by the fluorescently-labeled regions; and each of the fluorescently-labeled regions has a center that is located at least 200 nm from the centers of the other fluorescently-labeled regions.

In another aspect, the invention provides a population of nucleic acid barcode probes such as DNA barcode probes, wherein each probe comprises a nucleic acid nanostructure such as a DNA nanostructure having at least two fluorescently-labeled regions and a target binding moiety, wherein the locations of each of the fluorescently-labeled regions on the nucleic acid nanostructure are such that a pattern of the fluorescent labels of the nucleic acid barcode probe and the identity of the target binding moiety is determinable based on the emission of visible light by the fluorescently-labeled regions.

In some embodiments, each of the fluorescently-labeled regions has a center that is located at least about 25 nm, at least about 50 nm, at least about 100 nm, at least about 200 nm, or at least about 250 nm from the centers of the other fluorescently-labeled regions.

These and other aspects and embodiments of the invention will be described in greater detail herein.

BRIEF DESCRIPTION OF DRAWINGS

FIGS. 1A-1B. Design of the DNA nanotube based barcode. (FIG. 1A) Two schematic drawings of the Blue--Red-Green (BRG, “--” and “-” denotes larger and smaller inter-zone distance in the barcode, respectively) barcode with a segment diagram on the top and a 3D view at the bottom. The main-body of the barcode is a DNA nanotube formed from by dimerizing two origami monomers, each consisting of 28 segments with 42-bp (13.6 nm) length. The grey segment in the middle represents the junction where the two monomers are joined together through cross-hybridization between their scaffolds and staples. Three 84-bp zones of the nanotube are fluorescently labeled (shown as blue, red and green segments) to produce the BRG barcode with an inter-zone distance of 450-nm between the first two zones and 270-nm between the last two. Note that each zone is only labeled with one fluorophore species. The resulting barcodes are thus referred as single-labeled-zone barcodes. (FIG. 1B) 3D cartoons showing the details of one fluorescently labeled zone. Left: a scaffold-plus-staple model of such an 84-bp zone before labeling. Each of the twelve 63-base-long staples (shown in varying shades of grey) contains two parts: the 42-base region at the 5′-end weaves through three double-helices to fold the scaffold (shown in black) into a six-helix bundle nanotube; and the 21-base extension at the 3′-end protrudes out for fluorescent labeling. Middle: an identical but simplified model to emphasize the six-helix bundle structure (each helix shown as a semi-transparent grey cylinder) and the positioning of the twelve 21-base staple extensions (each shown as a light-grey curl). Right: Cartoon representation of a “green” 84-bp zone. The labeling is achieved by hybridizing the Cy3 (shown as glowing spheres at the 3′-ends) modified strands to the staple extensions.

FIGS. 2A-2C. Single-labeled-zone fluorescent barcodes. (FIG. 2A) Superimposed TIRF microscopy images of five barcode species (top) and the statistics from manual counting (bottom). From left to right are the BBB, BRG, BRR, GRG and RGB barcodes with a representative image on top of the corresponding bar-graph. Each bar-graph is generated based on the manual sorting and counting of the objects found in a 50×50 μm² image (˜40 barcodes, the exact sample size N is noted beside the corresponding bar-graph). (FIG. 2B) A representative image of the equimolar mixture of 27 barcode species. (FIG. 2C) Statistics obtained by analyzing twenty-seven 50×50 μm² images of the 27 barcode mixture (1,500 barcodes in total). Left: barcode counts of the 27 species (average count of 55 with a standard deviation of 9). A representative TIRF image (1.4×0.7 μm²) of each barcode type is placed underneath the corresponding bar. Right: sorting result of the observed objects shown as a pie-chart. The bar-graphs and the pie-chart include correct barcodes (qualified barcode with expected identity); incorrect barcodes (qualified barcode with unexpected identity); monomer nanotubes (one spot or two connecting spots); barcodes with wrong geometry (i.e., bending angle <120°); and barcodes containing at least one spot with two colors. In the 27-barcode pool, correct vs. incorrect barcodes were not distinguishable because all barcode types are expected. As a result the bars and pie representing the qualified barcodes in (FIG. 2C) are shown. Scale bars: 5 μm.

FIGS. 3A-3E. Representative TIRF and software reconstructed images of BRG and GRG nano-barcodes. (FIG. 3A) TIRF image of BRG nano-barcodes. (FIG. 3B) Software constructed image of (FIG. 3A), inset showing calculation of barcode bending angle. (FIG. 3C) TIRF image of BRG nano-barcodes. (FIG. 3D) Software constructed image of (FIG. 3C). (FIG. 3E) Theoretical designed distances between each region of BRG (upper) and GRG (lower) nano-barcodes. Scale bar: 10 pixels or 0.714 μm.

FIGS. 4A-4C. Schematic illustration and result of a 21-mer oligonucleotide detection using nano-barcodes. (FIG. 4A) A GRG barcode with a capture probe is biotinylated as a result of the target binding and a nude BRG barcode stays untouched. Note that the drawing is not to scale. (FIG. 4B) TIRF images of nano-barcodes immobilized on streptavidin coated glass cover-slip. Left: with target; Right: without target. (FIG. 4C) Statistical detection result showing the average barcode counts per 71.4×71.4 μm² area. Error bars represent the standard deviation.

FIGS. 5A-5D. Dual-labeled-zone fluorescent barcodes. (FIG. 5A) Typical TIRF microscopy images of five selected barcode species, shown both in separate channels and after superimposing. Scale bar: 5 μm. (FIG. 5B) Statistics obtained by analyzing two 50×50 μm² images of each barcode species (˜85 barcodes, the exact sample size N is noted beside the corresponding bar-graph). The barcode types are noted under the x-axis of the diagram. The bar graph includes correct barcodes (correct geometry and color identity); incorrect barcodes (correct geometry but incorrect color identity); monomer nanotubes (one spot or two connecting spots); and barcodes with wrong geometry (i.e., bending angle <120°). (FIG. 5C) Computer-aided barcode counting results of the 72-barcode pool (N=2,617) and the 216-barcode pool (N=7,243) plotted as bar-graphs with descending barcode counts from left to right (data not shown). A computer-generated reference barcode image is placed underneath the corresponding bar. (FIG. 5D) A table containing one representative TIRF image (1.4×0.7 μm²) for each of the 216 dual-labeled-zone barcode species.

FIGS. 6A-6C. Super-resolution fluorescent barcodes. (FIG. 6A) Scheme of DNA-PAINT used for super-resolution barcode imaging. The 400 nm nanotube consists of 4 binding zones spaced by ˜114 nm. Each zone can be decorated with the desired combination of “docking” sequences for imager strands. The orthogonal imager strands bind transiently to their respective “docking” sites on the nanotube, creating the necessary “blinking” for super-resolution reconstruction (FIG. 6B) Top: Segment diagram (similar to the one used in FIG. 1B) of the DNA nanotube monomers used for creating five barcodes for super-resolution imaging. Bottom: super-resolution images of the five barcodes shown in each channel separately and as an overlay of all channels. Scale bar: 100 nm. (FIG. 6C) Super-resolution image showing all five barcodes in one mixture. Scale bar: 500 nm.

FIGS. 7A-7B. Tagging yeast cells with the GRG barcodes as in situ imaging probes. (FIG. 7A) Cartoon illustrating the tagging mechanism. The biotinylated barcodes are anchored on the yeast cell through streptavidin molecules bound to biotinylated polyclonal antibodies coated on the yeast surface. Only two of the ten biotinylated staples on the barcode are shown here for clarity. (FIG. 7B) Overlaid microscope images (acquired in bright field and TIRF) of the yeast cells treated with the barcodes. Top: Yeast cells treated as illustrated in (FIG. 7A). Bottom: Negative control: yeast cells treated with non-biotinylated barcodes. Scale bars: 5 μm.

FIGS. 8A-8B. Fluorescent barcode with non-linear geometry. (FIG. 8A) A schematic of three identical ˜400-nm long DNA nanotubes are linked to the outer edge of a DNA ring with diameter of ˜60 nm through the hybridization between staple extensions. The ring and the end of the tube are labeled by Cy3 and Cy5, respectively. (FIG. 8B) A representative TIRF microscope image of the barcode shown in (FIG. 8A). Scale bar: 5 μm.

DETAILED DESCRIPTION OF INVENTION

Provided herein are nucleic acid (e.g., DNA) nanostructure barcode probes that are fully addressable and able to be read using standard fluorescent microscope.

Previously described molecular barcodes are constructed using one of two strategies: (1) By combining multiple spectrally non-overlapping fluorophores in a controlled molar ratio to generate a mixed color signature; or (2) by separating fluorophores beyond the diffraction limit (˜200 nm) and arranging them in a specific geometric pattern. The first category of barcode has been made, for example, from dendrimeric DNA (see, e.g., Li et al., Nat. Biotechnol. 23:885-889 (2005)), self-assembled 2D DNA arrays (see, e.g., Lin et al., Nano Lett. 7:507-512 (2007)) and quantum dots (see, e.g., Han et al., Nat. Biotechnol. 19:631-635 (2001)). The successful construction and decoding of such barcodes heavily depends on both the fluorescent labeling efficiency and the imaging instrument's ability to precisely detect different fluorescent intensity levels.

In contrast, barcodes constructed according to the second strategy are more robust, and can be constructed and detected even when the labeling efficiency and imaging conditions are sub-optimal. Furthermore, when such methods are used, the ability to multiplex increases exponentially with each additional fluorescent spot that is incorporated. Examples of barcodes that fall in this category include rare-earth doped glass microfibers (˜100 μm long) (see, e.g., Dejneka et al., Proc. Nat. Acad. Sci. USA 100:389-393 (2003)) and double-stranded linear DNA with one strand fluorescently tagged at specific locations (2-5 μm long) (see, e.g., Xiao et al., Nat. Methods 6:199-201 (2009) and Geiss et al., Nat. Biotechnol. 26:317-325 (2008)). However, existing methods using this strategy are limited both in the addressability of the fluorescent spots and because, in the absence of specialized equipment, the labeled barcodes will fold into a conformation that brings the fluorescent spots within the diffraction limit of visible light, rendering the barcode unreadable using a fluorescent microscope.

The instant inventors recognized that the problems associated with existing molecular barcode strategies could be addressed by using nucleic acid nanostructures such as DNA nanostructures to create novel molecular barcode probes. Nucleic acids such as DNA may be folded into predetermined one-, two- or three-dimensional nanostructures using a variety of techniques, such as DNA origami (Rothemund US-2007/0117109 A1), single-stranded tiles (Yin et al., “Programming DNA Tube Circumferences,” Science (2008): 321: 824-826), DNA hairpins (Yin et al. US-2009/0011956 A1; Yin et al., “Programming biomolecular self-assembly pathways,” Nature (2008) 451:318-323), and others.

In general, the DNA origami process involves the folding of one or more long, “scaffold” DNA strands into a particular shape using a plurality of rationally designed “staple” DNA strands. The sequences of the staple strands are designed such that they hybridize to particular portions of the scaffold strands and, in doing so, force the scaffold strands into a particular shape. Methods useful in the making of DNA origami structures can be found, for example, in U.S. Pat. App. Pub. Nos. 2007/0117109, 201008/0287668, 2010/0069621 and 2010/0216978, each of which is incorporated by reference in its entirety. Staple design can be facilitated using, for example, caDNAno software, available on the internet at the cadnano website.

In certain embodiments, a DNA nanostructure barcode probe may include a DNA nanostructure made of one or more scaffold strands held in a specific shape by rationally designed staple strands. The sequence listing provides the nucleotide sequence of a scaffold strand, as SEQ ID NO:1, that may be used to construct an exemplary DNA origami barcode probe. The sequence listing also provides nucleotide sequences of staple strands, as SEQ ID NOs: 13-361, that may be used to construct an exemplary DNA origami barcode probe, together with the scaffold strand represented by SEQ ID NO:1. As will be discussed in greater detail herein, SEQ ID NOs: 13-186 represent nucleotide sequences of staple strands used to form a front monomer and SEQ ID NOs: 187-361 represent nucleotide sequences of staple strands used to form a rear monomer in an exemplary DNA origami barcode probe. As used herein, the term “DNA nanostructures” is used for convenience and it is to be understood that the invention contemplates nucleic acid nanostructures generally. The nanostructures of the invention may be linear (e.g., nanorods) or non-linear (e.g., star-shaped, triangular, etc.).

The DNA nanostructure has at least two non-overlapping, fluorescently-labeled regions. In certain embodiments, the DNA nanostructure barcode probe has at least 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 non-overlapping, fluorescently-labeled regions.

The fluorophore pattern of the probe is determined using light microscopy. In some embodiments, each of the fluorescently labeled regions can be visibly distinguished using a fluorescent light microscope. In some of these embodiments, the center of each fluorescently labeled region is separated from the centers of other fluorescently labeled regions by a distance greater than the visible light diffraction limit of visible light (i.e. at least 200 nm). In certain embodiments, therefore, each fluorescently labeled region is at least 200 nm from any other fluorescently labeled region. In some embodiments, each fluorescently labeled region is at least 250 nm from any other fluorescently labeled region.

In some embodiments, even higher resolution is achievable and the fluorescently labeled regions may be spaced apart from each other at even shorter distances (i.e., a distance of less than 200 nm). Accordingly, in some embodiments, the distance between the fluorescently labeled regions may be equal to or about 175 nm, 150 nm, 125 nm, 100 nm, 75 nm, 50 nm, 25 nm, or smaller distances. When the fluorescently labeled regions are spaced apart at distances that are less than the diffraction limit of visible light, the barcoded probes are imaged using super-resolution techniques such as Point Accumulation for Imaging in Nanoscale Topography (PAINT, DNA-PAINT), Stimulated Emission Depletion Microscopy (STED), Reversible Saturable Optical Fluorescence Transitions (RESOLFT), Stochastic Optical Reconstruction Microscopy (STORM, dSTORM), Photoactivated Localization Microscopy (PALM), Blink Microscopy (BM), and any other form of super-resolution microscopy.

It is to be understood that the term “fluorescently-labeled region” embraces regions that are stably labeled and those that are transiently labeled with fluorophore-bearing moieties such as fluorophore-bearing oligonucleotides that are complementary to a handle domain or docking strand (or sequence), as described in greater detail herein. In some instances, the barcode probes of the invention are provided with such fluorophore-bearing oligonucleotides bound thereto, and therefore these probes would be fluorescent. In other instances, the barcode probes of the invention are provided without such fluorophore-bearing oligonucleotides bound thereto, and therefore these probes may not be fluorescent until they are bound to a fluorophore-bearing oligonucleotide. In these latter instances, a probe may be provided together with a plurality of fluorophore-bearing oligonucleotides that are specific for (e.g., typically, complementary to) the handle domains or docking strands of the probe. The probes and the oligonucleotides may be provided in a kit, optionally with each in a separate container within the kit.

The positions of the fluorescently labeled regions can be selected such that the orientation of the DNA nanostructure barcode may be determinable through visualization of the barcode on a fluorescent microscope (typically by some form of asymmetry in the arrangement of the labeled regions or by some arrangement convention, such a particular color or pattern reserved to indicate an end of the barcode). In some instances, orientation information is unnecessary and the barcode pattern need not be absolutely unique. Thus, barcodes with even just two labels may be used, and the presence and/or intensity of various labels provides the information required.

In some instances, the fluorescently labeled regions are arranged in a linear manner. An examples is shown in, for example, FIGS. 1A-1B. The fluorescently labeled regions may however be arranged in a non-linear manner as well. An example is shown in FIG. 8. Other non-linear arrangements will be apparent to those of ordinary skill in the art and are embraced by the invention. In some instances, a non-linear orientation (or arrangement or geometry) of the fluorescently labeled regions is used to detect and/or identify analytes. In some instances, the signal (including for example the color or color combination) of non-linearly arranged fluorescently labeled regions is used to detect and/or identify analytes. In still other instances, orientation and signal are used together to detect and/or identify analytes. Thus, it is to be understood that the nano structure may be linear or non-linear and/or the arrangement of the fluorescently labeled regions may be linear or non-linear.

The DNA nanostructure, once assembled, is sufficiently immutable in a resting state (i.e., in the absence of external influence from e.g. an electrical field) that the spatial pattern of the fluorescent regions can be detected using light microscopy in that resting state. Portions of the nanostructure may be flexible, such as unlabeled portions. In some embodiments, a probe may include a (relatively) rigid portion carrying label and an unlabeled flexible portion. In some embodiments, a probe may have two rigid labeled regions connected by a deformable linker.

In certain embodiments, the DNA nanostructure of the DNA barcode probe can be of any one-, two- or three dimensional shape that is able to support at least three fluorescently labeled regions at least 200 nm apart from each other. As stated herein, however, the invention is not so limited as nanostructures having fluorescently labeled regions spaced at distances of less than 200 nm from each other are also contemplated.

In certain embodiments, the DNA nanostructure is a nanotube. In some embodiments, the nanotube is at least 200, 300, 400, 500, 600, 700 or 800 nm long. In certain embodiments, the DNA nanostructure is a six helix bundle dimer nanotube. Description of DNA nanotube design (via DNA origami) can be found in, for example, Douglas et al., Proc. Natl. Acad. Sci. USA 104:6644-6648 (2006) and U.S. Pat. App. Pub. No. 2010/0216978, each of which is incorporated by reference in its entirety.

In some embodiments, the DNA barcode probes are designed such that the orientation of the DNA barcode probe is determinable based on the emission of visible light by the fluorescently-labeled regions. Any property of the barcode can be used to render the orientation of the DNA barcode can be determinable. For example, if the DNA barcode probe has a substantially one-dimensional (linear) structure, such as a nanotube, the fluorescently labeled regions can be positioned asymmetrically along the DNA nanostructure. The orientation of a substantially one-dimensional (linear) DNA barcode probe can also be made determinable by asymmetrically using a particular fluorophore or combination of fluorophores to label one side of the DNA nanostructure consistently. If the DNA nanostructure is two- or three-dimensional, the orientation of the DNA barcode probe can also be rendered determinable based, for example, on an asymmetry of the shape of the structure itself.

In certain embodiments, the fluorescently labeled regions of the DNA barcode probe are generated by labeling specific staples of the DNA nanostructure with a fluorescent moiety. The staples can be directly labeled or indirectly labeled. As used herein, the term “directly labeled” refers to a nucleic acid that is covalently bonded to a detectable moiety. In contrast, the term “indirectly labeled” refers to a nucleic acid that is attached to a detectable moiety through one or more non-covalent interactions.

In certain embodiments, certain staples of the DNA nanostructure are directly labeled with a fluorescent moiety. In such embodiments, the staple can be, for example, synthesized with a particular fluorescent moiety attached, or covalently bonded to a fluorescent moiety prior to its incorporation into the DNA nanostructure.

Any combination of fluorescent moieties may be used in a single barcode, provided the fluorescent signal from each labeled region is detectable. Preferably, the combination of fluorescent moieties is chosen so that there is no energy transfer between the fluorescent moieties (i.e., the fluorophore combination used on a single barcode probe does not contain pairs of fluorophores that act together as a donor-acceptor pair).

In some embodiments, certain staples of the DNA nanostructure are indirectly labeled with a fluorescent moiety. In such embodiments, such staples can be synthesized to have at least two domains, a staple domain and a handle domain. The staple domain is a region (or nucleotide sequence) of the staple that hybridizes to the scaffold strand to contribute to the formation and stability of the DNA nanostructure. The handle domain contains additional nucleic acid sequence that is not necessary for the creation of the DNA nanostructure. Before, during or after the formation of the DNA nanostructure, the handle sequences are available to be hybridized by oligonucleotides having a complementary DNA sequence. Thus, such staples can be indirectly labeled by hybridizing the handle domain to another nucleic acid that has a nucleic acid sequence complementary to the handle and that is itself either directly or indirectly labeled with a fluorescent moiety.

In some embodiments, each fluorescent region of the DNA barcode probe includes at least one fluorescently labeled staple. In certain embodiments, the fluorescently labeled region may include a plurality of fluorescently labeled staples. For example, in certain embodiments, each fluorescently labeled region may include at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, or more fluorescently labeled staples. In regions designed to have multiple staples labeled, all the staples may be labeled by a single type of fluorophore, or the staples may be labeled by a combination of fluorophore types. For example, in certain embodiments, a fluorescently labeled region is designed to be labeled by multiple types of fluorophores present at a predetermined ratio. An example of this latter type of labeling, referred to as dual-labeling, is demonstrated in the Examples. In dual-labeling, a single region is labeled with two fluorophores in a predetermined ratio, to yield a fluorescent signal that is distinguishable from either of the contributing fluorophores. In this way, the variety of barcode probes is increased.

In still other embodiments, the barcode probe may comprise one or more regions that are transiently labeled with fluorophore-bearing oligonucleotide strands. These embodiments may be used when the fluorescently labeled regions are within 200 nm of each other. In some embodiments, all the regions contributing to the barcode will be designed to be transiently labeled. Transient labeling of a region is achieved by using a nanostructure comprised of staple strands with handle domains that are shorter in length than those used for more permanent binding of a fluorescently labeled oligonucleotide. As an example, permanent (or stable) binding of fluorophore-bearing oligonucleotides to a handle domain of a staple strand can be achieved using oligonucleotides and handle domains that are about 21 nucleotides in length. When shorter oligonucleotides and handle domains are used, the strength of binding between the two is reduced and accordingly they are more likely to dissociate than are longer strands. At room temperature, oligonucleotides and handle domains that are about 9 nucleotides in length associate with each other only transiently. As will be understood in the art, at higher temperatures, the length of the oligonucleotide and handle domain will typically be increased in order to achieve the same association/dissociation kinetics.

Accordingly, the invention contemplates handle domains that are directly or indirectly labeled with fluorophores as well as those that are transiently labeled with fluorophores. The length of the handle domain (and similarly its complementary oligonucleotide) will depend upon the nature of the binding (i.e., whether it is intended to be permanent or transient binding), and the reaction conditions such as but not limited to temperature, salt concentration, and the like. Such lengths may range, without limitation, from about 5 nucleotides to 30 nucleotides, or from about 7 nucleotides to about 25 nucleotides, or from about 9 nucleotides to about 21 nucleotides.

In some embodiments, the DNA barcode probe may further include a target binding moiety that acts as a binding partner for the target (or analyte) of interest. As used herein, the term “binding” refers to an association between at least two molecules due to, for example, electrostatic, hydrophobic, ionic and/or hydrogen-bond interactions under physiological conditions. Such a target binding moiety can be, for example, without limitation, a nucleic acid such as an oligonucleotide, a protein or peptide such as an antibody or antibody fragment, a carbohydrate or a polysaccharide, or a small molecule. The target binding moiety and the target to which it binds can also be viewed in a receptor and ligand relationship. In certain embodiments, the DNA barcode probe may include multiple target capture moieties, which may be identical or different.

The target capture moiety can be attached to the DNA nanostructure of the DNA barcode probe using any method known in the art. For example, the target capture moiety can be covalently bonded to a staple strand or a scaffold strand. The capture moiety can also be indirectly attached to either a staple strand or the scaffold strand by, for example, hybridizing to a handle domain of a staple strand, as described above.

In certain embodiments, the DNA barcode probe may include a target binding moiety that is an oligonucleotide or other nucleic acid capable of hybridizing to a target nucleic acid. In general, an oligonucleotide is capable of hybridizing to a target nucleic acid if it includes a nucleic acid sequence that is substantially complementary a sequence of the target nucleic acid. In certain embodiments, the oligonucleotide may include a sequence that is perfectly complementary to a target (i.e. that is able to base pair at every nucleotide with the target sequence). In some embodiments, the oligonucleotide is less than perfectly complementary to the target but is still able to hybridize to a target nucleic acid under certain conditions. Thus, in certain embodiments the sequence of the oligonucleotide is at least 10%, 20%, 30%, 40%, 50%, 60%, 65%, 70%, 75%, 80%, 85%, 90% or 95% complementary to a sequence of the target nucleic acid. In certain embodiments, the DNA barcode probe may include a target binding moiety that is an aptamer.

In certain embodiments, the DNA barcode probe may include a target binding moiety that is an antibody. As used herein, the term “antibody” includes full-length antibodies and any antigen binding fragment (i.e., “antigen-binding portion”) or single chain thereof. The term “antibody” includes, but is not limited to, a glycoprotein comprising at least two heavy (H) chains and two light (L) chains inter-connected by disulfide bonds, or an antigen binding portion thereof. Antibodies may be polyclonal or monoclonal; xenogeneic, allogeneic, or syngeneic; or modified forms thereof (e.g., humanized, chimeric).

As used herein, the phrase “antigen-binding portion” of an antibody, refers to one or more fragments of an antibody that retain the ability to specifically bind to an antigen. The antigen-binding function of an antibody can be performed by fragments of a full-length antibody. Examples of binding fragments encompassed within the term “antigen-binding portion” of an antibody include (i) a Fab fragment, a monovalent fragment consisting of the V_(H), V_(L), CL and CH1 domains; (ii) a F(ab′)2 fragment, a bivalent fragment comprising two Fab fragments linked by a disulfide bridge at the hinge region; (iii) a Fd fragment consisting of the V_(H) and CH1 domains; (iv) a Fv fragment consisting of the V_(H) and V_(L) domains of a single arm of an antibody, (v) a dAb fragment (Ward et al., (1989) Nature 341:544 546), which consists of a V_(H) domain; and (vi) an isolated complementarity determining region (CDR) or (vii) a combination of two or more isolated CDRs which may optionally be joined by a synthetic linker. Furthermore, although the two domains of the Fv fragment, V_(H) and V_(L), are coded for by separate genes, they can be joined, using recombinant methods, by a synthetic linker that enables them to be made as a single protein chain in which the V_(H) and V_(L) regions pair to form monovalent molecules (known as single chain Fv (scFv); see e.g., Bird et al. (1988) Science 242:423 426; and Huston et al. (1988) Proc. Natl. Acad. Sci. USA 85:5879 5883). Such single chain antibodies are also intended to be encompassed within the term “antigen-binding portion” of an antibody. These antibody fragments are obtained using conventional techniques known to those with skill in the art, and the fragments are screened for utility in the same manner as are intact antibodies.

In certain embodiments the target binding moiety is a protein or peptide. For example, a protein or peptide can be used to bind the DNA barcode probe to the protein's ligand. DNA barcodes having protein or peptide target binding moieties can also be used, for example, to identify antibodies or receptors such as but not limited to cell surface receptors such as but not limited to T cell receptors and B cell receptors and intracellular receptors such as but not limited to hormone receptors that are able to bind to an epitope present on the protein or peptide.

In certain embodiments, the target binding moiety is a small molecule. DNA barcode probes having small molecule target binding moieties can, for example, be used to identify molecular or cellular targets of small molecules of interest. Furthermore, libraries of small molecules, where each small molecule is individually tagged with a DNA barcode, can be used in small molecule library screens to identify small molecules that specifically bind to a target of interest.

DNA barcode probes may be provided as a population of distinct species. The number of distinct barcode probes in the population is limited only by the multiplexing capability of the particular barcodes in the population. In certain embodiments, the population contains at least 10, 50, 100, 500, 1000, 2000, 3000, 4000, 5000, 10⁴, 50000, 10⁵, 10⁵, 10⁶, 10⁷, 10⁸, 10⁹, 10¹⁰, 10¹¹ distinct barcode probes. The population may contain 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, or more distinct species. The population may contain less than or equal to about 5, 10, 15, 20, 25, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 100 or more distinct species. In some embodiments, the population comprises 216 distinct barcode probes. The barcode probes described herein are sufficiently adaptable and expandable to permit creation of such large-scale populations of distinguishable species.

Methods of Use

The DNA nanostructure barcode probes can be used, inter alia, in any assay in which existing molecular barcode technologies are used. For example, the DNA barcode probes can be used according to the methods described in U.S. Pat. App. Pub. No. 2010/0015607, the content of which is incorporated by reference in its entirety.

Typically assays include detection assays including diagnostic assays, prognostic assays, patient monitoring assays, screening assays, biowarfare assays, forensic analysis assays, prenatal genomic diagnostic assays, and the like. The assay may be an in vitro assay or an in vivo assay. The sample being analyzed may be a biological sample, such as blood, sputum, lymph, mucous, stool, urine and the like. The sample may be an environmental sample such as a water sample, an air sample, a food sample, and the like. The assay may be carried out with one or more components of the binding reaction immobilized. Thus, the targets or the barcodes may be immobilized. The assay may be carried out with one or more components of the binding reaction non-immobilized. The assays may involve detection of a number of targets in a sample, essentially at the same time, in view of the multiplexing potential offered by the barcode probes of the invention. As an example, an assay may be used to detect a particular cell type (e.g., based on a specific cell surface receptor) and a particular genetic mutation in that particular cell type. In this way, an end user may be able to determine how many cells of a particular type carry the mutation of interest, as an example.

In certain embodiments, a method of identifying a target nucleic acid may include contacting the target nucleic acid with a DNA barcode having an oligonucleotide target capture moiety that includes a nucleic acid sequence capable of hybridizing to a sequence of the target nucleic acid. In certain embodiments, the target nucleic acid is contacted with a DNA barcode probe under conditions such that the target nucleic acid binds to the DNA barcode probe. In some embodiments, the target nucleic acid is then separated from at least some material that is not bound to the target nucleic acid. In certain embodiments the presence of the target nucleic acid is then determined by detecting the presence of the DNA barcode probe bound to the target nucleic acid. The detection of the DNA barcode probe can be accomplished by any appropriate method known in the art, including through fluorescent microscopy.

In some embodiments, the above-described method may further include immobilizing a capture probe containing a nucleic acid sequence complementary to a second target nucleic acid sequence to a solid support. In some embodiments the target nucleic acid is contacted with both the capture probe and the DNA barcode probe. The target nucleic acid can be contacted by the capture probe first, the DNA barcode probe first, or by both probes simultaneously. The capture probe can be immobilized on the solid support before hybridizing to the target nucleic acid, after hybridizing to the target nucleic acid, or simultaneously with hybridizing to the target nucleic acid. In such embodiments, the presence of the target nucleic acid will cause the formation of a tertiary complex that includes the capture probe, the target nucleic acid and the DNA barcode probe, immobilized to a solid support. As described above, the presence of the target nucleic acid is then determined by detecting the presence of the DNA barcode probe by any appropriate method known in the art, including through fluorescent microscopy

In certain embodiments, a method of identifying a target protein or cell may include contacting the target protein or cell with a DNA barcode probe described herein. In certain embodiments, the DNA probe has a protein, peptide or antibody target capture moiety. In some embodiments, the DNA barcode probe is contacted to a target cell or protein under conditions such that the target cell or protein binds to the DNA barcode probe. In some embodiments, the method further includes the step of separating the target protein or cell from at least some material that is not bound to the target protein or cell. In certain embodiments, the method further includes identifying a target protein or cell by detecting the presence of the DNA barcode probe bound to the target protein or cell. In some embodiments, the target protein is an antibody or receptor such as but not limited to a T cell receptor.

It will be appreciated that for some of the aspects and embodiments of the invention, it is preferable for the barcode probe and/or target to remain stationary during image acquisition, particularly if a super-resolution approach is being used and/or if the imaging technique requires superimposition of separately acquired images.

Super-Resolution Imaging

As discussed herein, in some aspects of the invention, the barcode probes comprise fluorescently labeled regions that are spaced at distances less than 200 nm (i.e., the diffraction limit of visible light). In some of these instances, the probe is contacted to a sample and once bound to one or more components of that sample it is exposed to soluble oligonucleotides each of which is specific for one of the regions and is labeled with fluorophores. Such soluble, transiently binding oligonucleotides may be referred to herein as “imager” strands. In some instances, the unbound components in the sample are removed prior to the addition of the fluorophore-bearing oligonucleotides. The presence of the barcode probe (and its identity based on its barcode) is then determined by imaging the remaining sample components using a series of single time lapsed images or a time lapsed movie in order to detect the binding of a fluorophore-bearing oligonucleotide to its complement on the probe. The complement on the probe may be referred to herein as a “docking” strand. The conditions are set such that at any given time only a single fluorophore-bearing oligonucleotide is bound to the barcode probe. If only a single fluorophore is bound at any given time, its color identity can be determined even if the neighboring regions are less than 200 nm away (since there would be no fluorophores bound to the neighboring regions at the same time). In this way, one is able to position adjacent “fluorescently labeled” regions at distances of less than 200 nm, and thereby generate an even greater diversity of barcodes. It is to be understood that in these embodiments, the fluorescently labeled regions are only transiently fluorescent and that the barcodes are only fluorescent when bound by imager strands.

In some embodiments, the imager and/or docking strands are about 5 to about 18 nucleotides in length, or about 6 to about 15 nucleotides in length, or about 7 to about 12 nucleotides in length. In some embodiments, the length is about 8, 9, 10, 11 or 12 nucleotides.

The art is familiar with other localization-based super-resolution fluorescence techniques including, for example, the STORM technique as described in U.S. Pat. No. 7,838,302, the disclosure of which relating to STORM is incorporated by reference herein. The invention contemplates labeling of the nanostructure barcode probes in any manner sufficient for any super-resolution technique.

In other aspects of the invention, the nanostructure barcode probes of the invention may be used to calibrate and/or confirm calibration of fluorescence microscopy equipment, including standard or conventional fluorescence microscopes, confocal microscopes, super-resolution fluorescence microscopes, and the like. Accordingly, nanostructure barcode probes may be used as calibration standards (or tools). Of particular interest in these instances are the barcode probes having “fluorescently-labeled” regions that are spaced apart at less than the diffraction limit of visible light (i.e., less than about 200 nm). When used in this manner, the probes may or may not have a target binding moiety. As an example, they may comprise a target binding moiety such as biotin or streptavidin that facilitates their immobilization for imaging purposes.

EXAMPLES Example 1: Creation of a DNA Barcode

DNA origami barcode probes were constructed by fluorescently labeling three separate regions of an 800-nm six-helix bundle dimer nanotube (FIG. 1). Each of the approximately 28 nm long fluorescently labeled regions was modified with twelve oligonucleotides attached to one of the three fluorophores (rhodamine-green, Cy3 or Cy5). The DNA origami barcode probe was designed to be asymmetric by placing the first two labeled regions further apart (approximately 460 nm apart) than the last two (approximately 270 nm apart). It is to be understood that other arrangements, including symmetric arrangements, are also contemplated by the invention.

The main structure of the DNA origami barcode probe is a DNA six-helix bundle nanotube dimer designed using the caDNAno software available at the cadnano website. The sequence of the scaffold strand used for each monomer is provided as SEQ ID NO:1. The sequences of the staples used in the construction of the DNA origami barcode are provided as SEQ ID NOs: 13-361. Certain selected staples were elongated (after rational design) to include 21-nt single stranded overhangs (handles) for fluorescent labeling. Table 1 provides the handle and anti-handle sequences used.

TABLE 1  DNA sequences used for fluorescently labeling nano-barcode. Name Sequence (SEQ. ID. NO.) Handle 1 5′-TTCCTCTACCACCTACATCAC-3′ (SEQ ID NO: 2) Handle 2 5′-TAACATTCCTAACTTCTCATA-3′ (SEQ ID NO: 3) “Blue” 5′-GTGATGTAGGTGGTAGAGGAA/rhodamine  anti-handle 1 green/-3′ (SEQ ID NO: 4) “Green” 5′-GTGATGTAGGTGGTAGAGGAATTT/Cy3/-3′ anti-handle 1 (SEQ ID NO: 5) “Red” 5′-GTGATGTAGGTGGTAGAGGAA/Cy5/-3′ anti-handle 1 (SEQ ID NO: 6) “Blue” 5′-TATGAGAAGTTAGGAATGTTA/Alexa  anti-handle 2 Fluor 488/-3′ (SEQ ID NO: 7) “Green” 5′-TATGAGAAGTTAGGAATGTTA/Cy3/-3′ anti-handle 2 (SEQ ID NO: 8) “Red” 5′-TATGAGAAGTTAGGAATGTTA/Cy5/-3′ anti-handle 2 (SEQ ID NO: 9)

Accordingly, of the staple strands provided in the Sequence Listing, SEQ ID NOs: 16, 17, 70-73, 126-129, 182 and 183 are labeled “blue”; SEQ ID NOs: 195, 196, 239, 240, 251, 252, 295, 296, 307, 308, 351 and 352 are labeled “red”; and SEQ ID NOs: 216-219, 272-275 and 328-331 are labeled “green”.

caDNAno JSON files showing the arrangement of the front and rear monomers of the probe are provided in the computer program listing appendix as “6ht-v5-1color-1.json” and “6ht-v6-2color-1.json” respectively.

To assemble the DNA origami barcode probe, the front and rear monomers were each assembled and fluorescently labeled in a separate test tube and then mixed together to form the dimer. The assembly of each monomer is accomplished in one-pot reaction by mixing 100 nM scaffold strand derived from M13 bacteriophage (termed p′7308) (SEQ ID NO:1) with a pool of oligonucleotide staple strands (SEQ ID NOs: 13-186 for the front monomer and 187-361 for the rear monomer; 600 nM of each; reverse-phase cartridge purified, Bioneer Inc.) in folding buffer containing 5 mM Tris, 1 mM EDTA, 20 mM MgCl₂, 50 mM NaCl (pH 8) and subjecting the mixture to a thermal-annealing ramp that cooled from 80° C. to 60° C. over the course of 80 minutes and then cooled from 60° C. to 24° C. over 15 hours. Excessive staples were removed by polyethylene glycol (PEG) fractionation before each monomer was incubated with anti-handles carrying appropriate fluorophores at 1:1.2 molar ratio for labeling. For dimerization, a stoichiometric amount of the fluorescently labeled front and rear monomers were mixed and incubated a 37° C. for 2 hours. The final product was purified by agarose gel (non-denaturing, 1.0%) electrophoresis. The purified nano-barcode can be stored at −20° C. for at least 3 months.

Although this example uses a barcode made of two monomers, a DNA barcode probe could include 3, 4, 5, or more monomers. The platform is therefore scalable to any desired level, and can provide any desired number of distinct probes.

Example 2: Detection of a Singly-Labeled DNA Barcode Using Fluorescent Microscopy

Two of the monomer nanotubes were folded and fluorescently labeled separately and combined together as described above to yield the nano-barcode. The final product was purified by agarose gel electrophoresis and directly deposited on a glass slide for imaging using a total internal reflection fluorescence microscope (TIRFM). In brief, 5 μL of the purified nano-barcode (˜20 pM) was deposited on a glass slide, sandwiched by a coverslip (No. 1.5, 18×18 mm², ˜0.17 mm thick) and let sit for 5 minutes before being imaged on a Leica DM16000B TIRFM. The samples were imaged sequentially through three channels, each assigned a false color (blue, green and red). For the blue channel, the 488 nm laser beam was reflected by a dichroic mirror (430/505/575/670) and shined on the sample through a 100× objective (HCX PL APO 100×/1.47 oil CORR TIRF, Leica). The emission light was collected through the same objective, filtered through the same dichroic mirror and an external emission filter (525/36) and integrated for 800 ms on an EM-CCD camera (Hamamatsu C9100-02). For the green and red channels, similar configurations were used except for the excitation laser (561 and 635 nm, respectively), emission filter (605/52 and 705/72, respectively) and exposure time (500 and 700 ms, respectively). The imaging process was automatically controlled by a Leica LAS software. The images were processed by Image J and a custom written software for decoding.

The following false-colors were assigned to the fluorescently labeled regions: Alexa Fluor 488/rhodamine green (blue), Cy3 (green) and Cy5 (red). TIRFM images resolved the DNA origami barcode as a strip of three distinct bright spots. Notably, the distance between blue and green spots is farther than that between green and red showing the asymmetry of the barcode (data not shown)

A DNA origami barcode system having three fluorescently labeled regions, each of which is labeled by one of three distinct fluorophores can generate 3³ (27) distinct DNA origami barcode probes. All 27 possible DNA origami barcode probes were assembled separately and purified together by agarose gel electrophoresis.

Five distinct barcodes from the 27 members in the barcode family were randomly chosen for quality control experiments. The barcodes were assembled and purified separately and imaged under the same experimental conditions. Two distinct features of the barcode were clearly visible from the TIRF images (FIG. 2A, top panel): first, each fluorescently labeled zone on a barcode was resolved as a single-color spot and each complete barcode consisted of three of such spots; Second, two of the neighboring spots were separated by a small gap while the other 7 two neighbors sat closely together. Therefore one can visually recognize and decode those geometrically encoded barcodes based on the color identity of the spots and their relative spatial positions, even without the aid of any specialized decoding software. Using a custom-written software that localizes the center of each spot on the BRG barcodes, we measured the average center-to-center distance between the neighboring spots to be 433±53 nm (mean±s.d., N=70; larger distance) and 264±52 nm (mean±s.d., N=70; smaller distance), confirming the correct formation of the barcodes. These experimentally measured distances were slightly smaller than the designed values (478 nm and 298 nm). We attribute this discrepancy to random thermal bending of the nanotubes (persistence length of ˜1-2 μm), which has been observed previously by others^(23,28) and confirmed by us (data not shown) using transmission electron microscopy (TEM). It is important to note that unlike some other geometrically encoded barcoding systems (e.g., NanoString nCounter¹²), there was no molecular combing step involved in the sample preparation. The separation between the fluorescent spots was exclusively created by the inherently rigid structure of the six-helix bundle nanotube. It is also notable that the spot intensities were not perfectly uniform across the whole image, which can be explained by factors such as the uneven illumination of the sample stage and differences in labeling efficiency. Nevertheless, the TIRF images proved that the barcodes were successfully assembled and can be resolved unambiguously. We then manually investigated TIRF images with an area of 50×50 μm² for the selected five barcodes (FIG. 2A, bottom panel). The objects found within the images were first sorted into qualified (i.e., three single-color spots arranged in a nearly linear and asymmetric fashion as designed) and unqualified (i.e., all other objects) barcodes. The qualified 8 barcodes were further categorized into correct and incorrect (false-positive) barcodes based on the fluorescent signatures of the composing spots to reflect whether the barcode was the expected type. The unqualified barcodes were further sorted into (1) monomer nanotubes (single spot or two “kissing” spots), (2) barcode with “wrong” geometry (i.e., extreme bending), and (3) barcode containing at least one spot with multiple colors. Our statistics revealed that more than 70% of the visible objects were qualified barcodes, which we further determined to be exclusively the expected type (i.e., zero false-positive out of 188 qualified barcodes observed). The unqualified barcodes arose likely from folding defects, sample damage during handling and overlapping nanotubes on the surface, which can be largely reduced by optimizing the sample preparation and imaging protocol.

Typically, a number of different barcode species coexist in one pool. Thus it is important to examine the robustness of our system by mixing different types of barcode together. In an initial test, we synthesized BRG and RGB barcodes separately, mixed them together at equal molar ratio and co-purified them via gel electrophoresis. The TIRF analysis of the purified mixture confirmed the 1:1 stoichiometry of the two barcodes and the overall assembly success rate (qualified barcode/all objects) of ˜80%, suggesting that both barcodes maintained their integrity in the mixing and co-purification process. In addition, over 98% of the qualified barcodes fell into one of the two expected types (BRG and RGB). The 2% false-positive rate was due to an unexpected barcode namely BGB, which could be attributed to a rare occasion when the front monomer of the BRG barcode lay in proximity of the rear monomer of the RGB barcode. This can be eliminated using a more stringent purification condition to minimize the amount of leftover monomers.

We next challenged the system by imaging a pool of all 27 members of the barcode family in which all species were mixed at equimolar amount. The TIRF images (FIG. 2B) showed that all types of barcodes were resolved. Statistics by sampling twenty-seven 50×50 μm² images (1,500 barcodes in total) revealed an average count of 55 per barcode type with a standard deviation of 9 (FIG. 2C), fitting well with the expected stoichiometry considering the pipetting and sampling error. The distribution of observed objects over the four categories (note that here correct vs. incorrect barcodes were not distinguishable as all 27 types were included) was consistent with the values measured from the single-type barcode samples. The above observations suggest that the sub-micrometer-long DNA nanotube represents a reliable platform to construct geometrically encoded barcodes with built-in structural rigidity.

Software could be used to recognize and decode the image of different types of DNA origami barcode probes automatically. Typically, such software has three basic steps: recognition, filtering and decoding. In the first step, the fluorescent spots are identified. For each fluorescent channel (blue, red or green), the software identifies fluorescent spots based on their intensity and size, then compares them to automatically determined thresholds using overall image intensity and pre-defined spot sizes. The fluorescent spots below those thresholds are removed along with general background noise. After processing all three channels, a barcode image is constructed by merging spots identified in three channels. An example of such a barcode image is provided in FIG. 3. In the second step, the distances (calculated from (x,y) coordinates of fluorescent spots) between each region of DNA origami barcode probes and the barcode bending angle (based on the center spot) are calculated. The software then filters DNA origami barcode probes and removes those with region distances that disagreed with the theoretical region distances or had a barcode bending angle smaller than a currently arbitrarily set threshold angle of 140 degrees. As an example, the BRG barcodes were filtered using three distance rules: (1) The distance between blue and green spot cannot be greater than 15 pixels (theoretical distance was 11 pixels); (2) The distance between red and blue spot cannot be greater than 9 pixels (theoretical distance was 6.8 pixels); and (3) The distance between red and green spot cannot be greater than 6 pixels (theoretical distance was 4.2 pixels). The BRG barcodes that had a bending angle (at the red spot) smaller than 140 degrees were removed. In the last step, after all barcodes are identified and filtered, the software uses different criteria (based on theoretical distance and color) to sort barcodes into specific types. Therefore, multiple types of DNA barcode probes can be decoded based on how they were originally designed. Besides the final constructed DNA barcode probe image, the software can output statistical information regarding the (x,y) coordinates of each DNA barcode probe fluorescent spot, distances between adjacent spots, barcode bending angle, and barcode types.

The software described above was used to detect BRG and GRG DNA origami barcode probes. As shown in FIG. 3, the BRG and GRG DNA origami barcode probes were clearly identified by the automated decoding software. The software used a number of filters to select the valid DNA origami barcode probes. As a result, 88% and 85% of BRG and GRG nano-barcodes were counted. The software generated statistical information on BRG and GRG barcodes (Table 2) that showed that the measured distances between each region on those DNA origami barcode probes were in good agreement with the theoretical region distances as designed (FIG. 3E).

TABLE 2 Barcode Barcode Barcode bending Barcode iden- dis- angle α Distance 1 Distance 2 type tified carded (degree) (pixel) (pixel) BRG 70 9 165.11 ± 10.08 6.18 ± 0.76 3.77 ± 0.74 GRG 81 15 161.51 ± 11.73 6.12 ± 0.95 3.95 ± 0.98

Example 3: Detection of an Oligonucleotide Target Using a DNA Barcode Probe

A 42-nt DNA oligonucleotide target was detected using a DNA origami barcode probe. Two different purified barcodes Green, Red, Green (GRG) with the 21-nt oligonucleotide target capture moiety specific for a 42-nt oligonucleotide target (Target 1, see Table 3 for sequences) and Blue, Red, Green (BRG) without a target capture moiety, were mixed at 1:1 ratio and diluted to 20 pM in folding buffer. Biotin probe specific for Target 1 (0.2 μL of 100 nM) and Target 1 (0.4 μL of 10 nM) was added to 100 μL of the barcode mixture. In a separate test tube containing 100 μL of the barcode mixture, 0.2 μL of 100 nM biotin probe for Target 1 and 0.4 μL of 1× folding buffer was added as a negative control. The above samples were both incubated at 37° C. overnight before being run through separate channels of a micro-fluidic cell with a streptavidin coated glass cover-slip (Xenopore) substrate. Both channels were then washed with 40 μL of washing buffer (5 mM Tris-HCl pH 8.0, 500 mM NaCl) and imaged on a Leica TIRFM as described above. Ten images were taken in each channel at random locations and the total number of DNA origami barcode probes was counted manually.

TABLE 3  DNA sequences used in oligonucleotide target detection Name Sequence (SEQ ID NO:) Target  5′-GAATCGGTCACAGTACAACCGCGCCGTAGGGCTG- oligo ATCAAAGC-3′ (SEQ ID NO: 10) Biotin  5′-/Biotin/GCTTTGATCAGCCCTACGGCG-3′ probe (SEQ ID NO: 11) Capture 5′-CGGTTGTACTGTGACCGATTC-3′ probe (SEQ ID NO: 12)

In the presence of the target oligonucleotide, the biotin probe hybridized to one 21 nt sequence of the target oligonucleotide, while the GRG barcode hybridized to a second 21 nt sequence of the target oligonucleotide. The BRG probe, however, lacking a target capture moiety specific for the target oligonucleotide does not hybridize to the target and therefore does not become bound by the biotin probe. (FIG. 4A). As a consequence, when the detection reaction mixture was run through the streptavidin-coated glass surface, the GRG barcode binds to the surface, while BRG barcode is washed away. TIRF images and statistical analysis supported the specificity of the detection (FIGS. 4B and C). In the presence of 40 pM oligonucleotide target, there were ˜20 times more GRG barcodes than BRG barcodes bound to the surface. In the absence of the target, both barcodes did not show significant surface binding.

Example 4: Dual-Labeled Barcode Probes

In order to enhance multiplexing capability even further, the sequence of six staple extensions per zone was changed so that instead of using twelve identical fluorescent oligonucleotides for labeling, a combination of up to two fluorophores was used to create more unique fluorescence signatures (pseudo-colors) for each zone. Six pseudo-colors (B, R, G, BG, BR, and GR) were generated by this “dual-labeling” strategy using three spectrally differentiable fluorophores. Consequently, the total number of distinct barcodes was raised from 27 to 6³=216, which represented an order of magnitude increase in the multiplexing capability.

Similar to the single-labeled-zone barcode family, 5 members from the dual-labeled-zone barcode family were chosen for quality control purpose. The barcodes can be visually decoded either solely from the superimposed image or by examining all different channels simultaneously. For example, as shown in the first column of FIG. 5A, the barcode “BG--GR-BR” (“--” and “-” denotes larger and smaller inter-zone distance in the barcode, respectively) exhibited two spots each in the blue, green and red channels but with descending gaps between them, matching its design. In the superimposed image, the barcodes were seen as Cyan--Yellow-Pink, an expected consequence of color mixing caused by the dual-labeling strategy. In a similar fashion, we further verified the correct formation of the other four selected barcodes (FIG. 5A). Although the final pseudo-color from the dual-labeled zones was not always uniform (e.g., some yellow spots were green-tinted while the others were red-tinted) due to the inconsistent labeling efficiency and minor sample displacement during imaging, the fluorescence signature of any given spot could be identified by checking the raw images acquired from the three imaging channels. We manually analyzed two 50×50 μm² images of each dual-labeled-zone barcode and plotted the statistical data in FIG. 5B. Here, objects were sorted into qualified barcodes and unqualified barcodes based on their geometry and the qualified ones were further categorized as correct and incorrect. 75-95% of the objects were qualified barcodes, among which 80-90% were the correct type (percentage varies depending on the exact type of barcode). Compared to the single-labeled-zone barcode family, the percentage of qualified barcodes remained the same, while the false positive rate increased significantly from zero to 10-20%. This observed increased false positive rate is consistent with the expected decreased robustness of the dual-labeling strategy (as compared to single-labeling). In one design, a dual-labeled zone carried 6 staple extensions for each fluorophore species, only half as many as in a single-labeled zone.

As a result, the dual-labeled-zone barcode consisted of dimmer spots that were more susceptible to damages such as photo bleaching. In this sense, a single-labeled-zone barcode can be thought of as a redundantly encoded dual-labeled-zone barcode. For instance, a single-labeled-zone barcode can still be recognized as the correct type when six fluorophores were missing from each zone, a scenario in which the dual-labeled-zone barcode could be disqualified or categorized as incorrect. In the latter case, it will increase the false positive rate. In principle, the false positive rate can be decreased by increasing the copy number of each fluorophore species in a dual-labeled zone. The five barcodes we examined have each of their zones labeled with two distinct fluorophore species, making them likely among the most error-prone members of the dual-labeled-zone barcode family. Therefore, we would expect a smaller false-positive rate on average from the whole family.

We further tested the dual-labeled-zone barcoding system by imaging a mixture containing 72 barcode species that were individually assembled and co-purified. Custom MATLAB scripts were used to assist the decoding process in two steps. In step one, a three-channel (red, green, blue) TIRF image containing barcodes was pre-processed to remove background and thresholded so that only pixels containing qualified barcodes remained. The resulting three-channel binary image was merged to generate a single-channel binary image. Next, the software identified the location and orientation of geometrically legitimate barcodes based on their shape in the binary image. In step two, for each barcode located in step one, the corresponding region of the three-channel image was compared against a library of all possible reference barcodes. The observed barcode was assigned the identity of the reference barcode with the highest correlation. The fully automated decoding process (unsupervised mode) ended after the above two steps. In an optional supervised mode, the software presented the user with the observed barcode and its most likely identity for approval. Comparison between supervised and unsupervised decoding results confirmed >80% agreement between the computer and the user. The computer-aided (supervised mode) analysis of thirty-six 64×64 μm² three-channel images registered ˜2,600 qualified barcodes that belonged to 116 different species (FIG. 5C, top panel). The expected 72 species constituted ˜98% of the total barcode population with an average barcode count of 36 per species and a standard deviation of 8. In contrast, the unexpected species averaged only ˜1.4 barcodes per species (maximum 4 counts).

Finally, we analyzed a mixture containing all the 216 members of the dual-labeled-zone barcode. Sixty 64×64 μm² images of this mixture were processed by the decoding software in the unsupervised mode. The fully automated analysis registered ˜34 barcode counts per species (˜7,200 barcodes total) with a standard deviation of 17 (FIG. 5C, bottom panel). The relatively large standard deviation could be attributed to the decoding error in the fully automated data analysis. Our study demonstrated that 216 barcode species were successfully constructed and resolved (FIG. 5D).

Example 5: Super-Resolution Barcode Probes

Barcodes with higher spatial information density were also generated using geometrically encoded super-resolution barcodes with fluorescent features spaced by ˜100-nm.

As a feasibility demonstration of the latter approach, we applied DNA-PAINT³¹, a recently developed super-resolution fluorescence technique, to image the barcodes. Over the last years, several techniques have been developed that allow imaging beyond the diffraction limit using far-field fluorescence microscopy⁴⁰⁻⁴⁴. In most super-resolution implementations, fluorophores are switched between fluorescence ON- and OFF-states, so that individual molecules can be localized consecutively. In methods relying on targeted readout schemes such as in Stimulated Emission Depletion Microscopy⁴⁵ (STED) or other Reversible Saturable Optical Fluorescence Transitions⁴⁰ (RESOLFT) techniques, fluorescence emission is actively confined to an area below the diffraction limit. Switching of fluorescent molecules can also be carried out stochastically such as in (direct) Stochastic Optical Reconstruction Microscopy^(46,47) (STORM, dSTORM), Photoactivated Localization Microscopy⁴⁸ (PALM) and Blink Microscopy⁴⁹ (BM) where most fluorescent molecules are “prepared” in a dark state and only stochastically switched on to emit fluorescence. In Point Accumulation for Imaging in Nanoscale Topography⁵⁰ (PAINT), fluorescence switching is obtained by targeting a surface with fluorescent molecules. In all stochastic approaches, fluorescence from single molecules is localized^(51,52) in a diffraction-limited area to yield super-resolved images. DNA-PAINT uses transient binding of fluorescently labeled oligonucleotides (imager strands) to complementary “docking” strands on DNA nanostructures to obtain switching between a fluorescence ON- and OFF-state, which is necessary for localization-based super-resolution microscopy (cf. FIG. 6A). By adjusting the length of the imager/docking strand duplex and the concentration of imager strands in solution, fluorescence ON- and OFF-times can be tuned independently.

For this study, we extended the DNA-PAINT technique to three-color imaging using orthogonal imager strand sequences coupled to three spectrally distinct dyes (Atto488 for blue, Cy3b for green and Atto655 for red excitation). To demonstrate the feasibility of the three-color super-resolution barcode system, we designed a DNA nanotube monomer with 4 binding zones in a symmetric arrangement. The neighboring zones were separated by ˜114 nm (i.e., well below the diffraction limit). Each binding zone consists of 18 staple strands, which can be extended to display three groups of orthogonal sequences (six per group) for the red, green or blue imager strands to bind. As a proof-of-principle experiment, we designed five different barcodes (FIG. 6A and top panel of B). The bottom panel of FIG. 6B shows the super-resolution reconstruction of the five barcodes for each channel separately as well as an overlay of all channels. FIG. 6C shows a larger area containing all five barcodes. The unique pattern of the barcodes in all three channels can be resolved. Some barcodes moved during the sequential imaging of all three color channels, but were still resolvable. Imaging could be improved by alternating excitation and faster image acquisition to prevent this effect. The transient, repetitive binding of imager strands to docking sequences on the nanotube not only creates the necessary “blinking” behavior for localization but also makes the imaging protocol more robust, as DNA-PAINT is not prone to photo-bleaching or incorrectly labeled strands. With the microscope setup we used, DNA-PAINT provides a resolution of ˜46 nm (FWHM of a Gaussian fit to the reconstructed PSF) in the red, ˜25 nm in the green and ˜29 nm in the blue channel. The lower resolution in the red imaging channel is a result from weaker laser excitation power. When using a higher power TIRF system, a resolution of 24 nm, similar to the green and blue channel can be obtained. The obtainable resolution and imaging specificity suggests that 6 positions on one nanotube monomer could be robustly resolved while keeping the geometrical asymmetry of the barcode, which would lead to 6⁷=279,936 possible different barcodes. Furthermore the modularity of the nanotube design enables the customized reengineering of barcodes with inter-zone distances tailored to the resolving power of the used microscope, thus making it applicable for a wide range of microscope setups.

Example 6: In Situ Labeling

In a proof-of-principle experiment, the GRG barcode was used to tag wild-type Candida albicans yeast. The yeast cells were first mixed with a biotinylated polyclonal antibody specific to C. albicans, then coated with a layer of streptavidin, and finally incubated with biotinylated GRG barcodes (FIG. 7A). TIRF microscopy revealed the barcodes attached to the bottom surface of the yeast cells (FIG. 7B, top panel). While some of the nanotubes landed awkwardly on the uneven cell walls of the yeast cells, a number of GRG barcodes can be clearly visualized. In contrast, no barcode tagging was observed when non-biotinylated antibodies or barcodes were used to treat the yeasts (FIG. 7B, bottom panel), suggesting that little to no non-specific interaction existed between the barcode and the cell surface.

Example 7: Non-Linear Labeled Nanostructures

DNA nanostructures with non-linear geometry could be assembled to generate more sophisticated barcodes. FIG. 8 shows an example where three ˜400 nm DNA tubes were linked to the outer edge of a ˜60 nm DNA ring through hybridization between the staple extensions (FIG. 8A, inset). Fluorescently labeling the ring and the far end of the nanotubes generated a three-point-star-like structure clearly resolvable under fluorescence microscopy. TIRF microscopy and TEM studies (FIG. 8B) revealed that about 50% of successfully folded barcodes featured three nanotubes surrounding the ring with roughly 120° angle between each other as designed, while many other barcodes had significantly biased angles between neighboring nanotubes due to the semi-flexible double-stranded DNA linker between the ring and the nanotubes. It is conceivable that using similar design to connect three identical “satellite” linear barcodes to a central hub (here the three satellite barcodes may share the hub as a common fluorescently labeled zone), one can construct barcodes with triplicated encoding redundancy that feature outstanding reliability. In addition, more rigid linkers between the ring and the protrusions (e.g., multi-helix DNA with strand crossovers) could be employed to enforce better-defined barcode geometry.

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EQUIVALENTS

Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents of the specific embodiments of the subject matter described herein. Such equivalents are intended to be encompassed by the following claims.

All publications, patents, and patent applications cited in this specification are herein incorporated by reference to the same extent as if each individual publication or patent application was specifically and individually indicated to be incorporated by reference. 

What is claimed is:
 1. A method of detecting a target comprising: contacting a sample with a nucleic acid barcode probe comprising a nucleic acid nanorod bound to a target-binding moiety, wherein the nucleic acid nanorod comprises a distinct barcode pattern formed by the position and color of at least two fluorescently-labeled regions that are separated from each other by a fixed distance of at least 200 nm; and determining whether the nucleic acid barcode probe binds to one or more components in the sample, wherein binding of the nucleic acid barcode probe to one or more components in the sample indicates presence of a target in the sample.
 2. The method of claim 1, further comprising identifying the target based on the position and color of the fluorescently labeled regions of the nucleic acid barcode probe bound to one or more components of the sample.
 3. The method of claim 1, wherein the at least two fluorescently labeled regions of the nucleic acid barcode probe comprise soluble, transiently binding fluorophore-bearing oligonucleotides.
 4. The method of claim 1, wherein the at least two fluorescently labeled regions of the nucleic acid barcode probe comprise stably bound fluorophore-bearing oligonucleotides.
 5. A method of detecting a target comprising contacting the target with a nucleic acid barcode probe that comprises a nucleic acid nanorod bound to a target-binding moiety, wherein the nucleic acid nanorod comprises a distinct barcode pattern formed by the position and color of at least two fluorescently-labeled regions that are separated from each other by a fixed distance of at least 200 nm; separating the target from material that is not bound to the target; and detecting the presence of the nucleic acid barcode probe bound to the target.
 6. The method of claim 5, further comprising identifying the target based on the position and color of the fluorescently labeled regions of the nucleic acid barcode probe bound to the target.
 7. The method of claim 5, wherein the at least two fluorescently labeled regions of the nucleic acid barcode probe are labeled with soluble, transiently bound fluorophore-bearing oligonucleotides.
 8. The method of claim 5, wherein the at least two fluorescently labeled regions of the nucleic acid barcode probe comprises stably bound fluorophore-bearing oligonucleotides.
 9. The method of claim 1, wherein the nucleic acid nanorod is a DNA nanorod.
 10. The method of claim 1, wherein at least two of the fluorescent labels are separated from each other by a structurally rigid region of the nanorod.
 11. The method of claim 1, wherein the nucleic acid nanorod comprises a scaffold strand and a plurality of staple strands.
 12. The method of claim 11, wherein the staple strands are labeled with a fluorophore, and the fluorophore-labeled staple strands comprise (a) a staple domain hybridized to the scaffold strand and (b) a handle domain.
 13. The method of claim 12, wherein the handle domain is hybridized to a fluorophore-labeled oligonucleotide.
 14. The method of claim 1, wherein the target-binding moiety is a single-stranded nucleic acid, or a protein or peptide.
 15. The method of claim 14, wherein the protein is an antibody.
 16. The method of claim 1, wherein the target is a target nucleic acid, a target protein or peptide, a target cell, or a combination thereof.
 17. The method of claim 1, wherein binding of the nucleic acid barcode probe to one or more components in the sample is determined by fluorescent microscopy.
 18. The method of claim 1, wherein the fluorophores are arranged in a geometric pattern.
 19. The method of claim 1, wherein each of the fluorescently-labeled regions has a center that is located at least 200 nm from any other center of a fluorescently-labeled region on the probe.
 20. The method of claim 5, wherein each of the fluorescently-labeled regions has a center that is located at least 200 nm from any other center of a fluorescently-labeled region on the probe. 